Sex-specific effects of COMT Val158Met polymorphism on corpus callosum structure: A whole-brain diffusion-weighted imaging study

(1)

HAL Id: hal-01613168

https://hal.sorbonne-universite.fr/hal-01613168

Submitted on 9 Oct 2017

HAL is a multi-disciplinary open access

archive for the deposit and dissemination of

sci-entific research documents, whether they are

pub-lished or not. The documents may come from

teaching and research institutions in France or

abroad, or from public or private research centers.

L’archive ouverte pluridisciplinaire HAL, est

destinée au dépôt et à la diffusion de documents

scientifiques de niveau recherche, publiés ou non,

émanant des établissements d’enseignement et de

recherche français ou étrangers, des laboratoires

publics ou privés.

Distributed under a Creative Commons Attribution| 4.0 International License

Sex-specific effects of COMT Val158Met polymorphism

on corpus callosum structure: A whole-brain

diffusion-weighted imaging study

Wissam El-Hage, Helen Clery, Frederic Andersson, Isabelle Filipiak, Michel

Thiebaut de Schotten, Bénédicte Gohier, Simon Surguladze

To cite this version:

Wissam El-Hage, Helen Clery, Frederic Andersson, Isabelle Filipiak, Michel Thiebaut de Schotten,

et al.. Sex-specific effects of COMT Val158Met polymorphism on corpus callosum structure: A

whole-brain diffusion-weighted imaging study. Brain and Behavior, Wiley Open Access, 2017, 7 (9),

pp.e00786. �10.1002/brb3.786�. �hal-01613168�

(2)

Brain and Behavior. 2017;7:e00786.

|

1 of 8 https://doi.org/10.1002/brb3.786

wileyonlinelibrary.com/journal/brb3 O R I G I N A L R E S E A R C H

Sex- specific effects of COMT Val158Met polymorphism on

corpus callosum structure: A whole- brain diffusion- weighted

imaging study

Wissam El-Hage

1,2,3

_{| Helen Cléry}

1

_{| Frederic Andersson}

1

_{| Isabelle Filipiak}

1

_|

Michel Thiebaut de Schotten

4,5

_{| Benedicte Gohier}

6

_{| Simon Surguladze}

7,8

This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

1_{Université François-Rabelais de Tours, Inserm} UMR U930 ‘Imagerie et Cerveau’, Tours, France 2_{Clinique Psychiatrique Universitaire, CHRU} de Tours, Tours, France 3_{Inserm 1415, Centre d’Investigation} Clinique, CHRU de Tours, Tours, France 4_{Inserm U1127, UPMC-Paris6, UMR-S} 975, CNRS UMR 7225, Brain and Spine Institute, Groupe Hospitalier Pitié-Salpetrière, Paris, France 5_{Brain Connectivity and Behaviour} Group, Frontlab, Brain and Spine Institute, Paris, France 6_{Department of Psychiatry, CHU d’Angers,} Angers, France 7_{Institute of Psychiatry, Psychology &} Neuroscience, King’s College London, London, UK 8_{Social & Affective Neuroscience} Laboratory, Ilia State University, Tbilisi, Georgia Correspondence Wissam El-Hage, Université François-Rabelais de Tours, Inserm UMR U930 ‘Imagerie et Cerveau’, Tours, France Email: wissam.elhage@univ-tours.fr

Abstract

Background: Genetic polymorphisms play a significant role in determining brain mor-phology, including white matter structure and may thus influence the development of brain functions. The main objective of this study was to examine the effect of Val158Met (rs4680) polymorphism of Catechol- O- Methyltransferase (COMT) gene on white matter connectivity in healthy adults.

Methods: We used a whole- brain diffusion- weighted imaging method with Tract- Based Spatial Statistics (TBSS) analysis to examine white matter structural integrity in intrinsic brain networks on a sample of healthy subjects (N = 82).

Results: Results revealed a sex- specific effect of COMT on corpus callosum (CC): in males only, Val homozygotes had significantly higher fractional anisotropy (FA) com-pared to Met-carriers. Volume- of- interest analysis showed a genotype by sex interac-tion on FA in genu and rostral midbody of CC, whereby Val males demonstrated higher FA than Met females. Conclusions: These results demonstrate the key effect of genes by sex interaction, rather than their individual contribution, on the corpus callosum anatomy. K E Y W O R D S COMT polymorphism, Diffusion-weighted imaging (DWI), sex effect, tract-based spatial statistics (TBSS), white matter

1 | INTRODUCTION

Genetic polymorphisms play significant role in determining brain mor-phology, including white matter structure and may thus influence the development of brain functions. Developmental studies showed that dopamine (DA) is one of the earliest neuromodulators expressed in the developing brain that plays a role in the neuronal maturation and myelination (Bartzokis, 2011; Money & Stanwood, 2013). Increased dopamine presence in the frontal cortex may also cause white matter

abnormalities. For instance, mice exposed to a copper chelator cupri-zone show a higher level of dopamine in the frontal cortex associated with brain demyelination, myelin breakdown, and loss of oligodendro-cytes (Xu et al., 2009; Xu, Yang, McConomy, Browning, & Li, 2010). However, the link between the genetic mechanisms underlying DA functionality and its relationship with white matter integrity in the liv-ing human brain remains poorly understood.

One of the most frequently studied dopaminergic genes is Catechol- O- methyltransferase (COMT) gene located within the q11

(3)

2 of 8

|

EL- HAGE EtAL.

of the 22nd chromosome (Bertocci et al., 1991; Deutch & Roth, 1990; Grossman, Emanuel, & Budarf, 1992). The COMT gene is involved in the metabolic degradation of catecholamines, notably synaptic do-pamine, especially in the prefrontal cortex (Männistö & Kaakkola, 1999; Mattay et al., 2003; Tunbridge, Bannerman, Sharp, & Harrison, 2004). This gene is associated with several allelic variants, including the COMT Val158Met (rs4680), a functional single- nucleotide poly-morphism that codes for a substitution of methionine (Met) for valine (Val) at codon 158. Previous studies have shown that this Met substi-tution reduces the activity of COMT enzyme to one- quarter of what is originally encoded by the Val allele (Lachman et al., 1996; Lotta et al., 1995).

The COMT Val158Met polymorphism may impact prefrontally mediated cognition (Meyer- Lindenberg & Weinberger, 2006). Several studies showed that Met-carriers performed better in cognitive tasks that involve prefrontal cortex functionality notably working mem-ory and cognitive flexibility tasks, compared with Val homozygotes. This effect was found independently of diagnosis, for example, in healthy controls, individuals with schizophrenia and schizotypal dis-order (Goldberg et al., 2003; Malhotra et al., 2002; Minzenberg et al., 2006). However, a meta- analysis (Barnett, Scoriels, & Munafò, 2008) highlighted that the relationship between COMT and cognitive per-formance was not always evident. More recently, a large population- based study (Wardle, de Wit, Penton- Voak, Lewis, & Munafò, 2013) has not found any effect of COMT on working memory. The authors suggested that the COMT effects are better detectable in neurophys-iological experiments rather than in purely cognitive tasks. fMRI stud-ies have indeed demonstrated COMT effect on Blood Oxygenation Level Dependent (BOLD) signal in people performing working mem-ory tasks (Egan et al., 2001; Mattay et al., 2003). However, the meta- analytical data on this topic has been inconsistent. Meta- analysis by Mier, Kirsch, and Meyer- Lindenberg (2010) reported significant asso-ciation between the COMT genotype and prefrontal activation in ex-ecutive function tasks, whereas the most recent meta- analytical paper indicated that there is presently no (significant) spatial convergence of imaging genetics findings on this association (Nickl- Jockschat, Janouschek, Eickhoff, & Eickhoff, 2015).

As well as studying the effect of COMT on brain functions, the investigators have been increasingly looking at possible associations between COMT polymorphisms and brain structure, for example, brain white matter as indexed by fractional anisotropy (FA). Shimony et al. (1999) used quantitative diffusion anisotropy MR images ob-tained from 13 healthy adults to evaluate white matter integrity. Their results showed that the FA measure reflects density and my-elination of fibers, as well as directional coherence, which could contribute to efficient signal transmission. Thomason et al. (2010) examined COMT gene- related differences in four white matter fiber tracts (genu of the corpus callosum, anterior thalamic radiation, in-ferior fronto- occipital fasciculus, uncinated fasciculus) in a group of 40 children (aged 9–15). The authors reported a significantly higher FA in Val- allele homozygotes (vs. Met/Val heterozygotes and Met allele homozygotes) in the genu of corpus callosum and anterior thalamic radiation, respectively. Based on animal studies showing

increase in DA availability due to inhibition of COMT functional-ity (e.g., Tunbridge et al., 2004), the authors suggested that lower FA measures in Met-carriers were associated with higher dopa-mine availability that may have inhibited myelination. Their results were in accordance with those of Liu et al. (2010) who employed a haplotype- based approach to assess the effect of COMT gene poly-morphisms on white matter integrity. The authors found that the groups with lower COMT enzymatic activity (i.e., potentially higher dopamine levels) had lower FA values in the prefrontal white matter tracts.

However, the main effect of COMT was not replicated in a study of Kohannim et al. (2012). This voxelwise analysis study reported a combined effect of five genetic SNPs, that is, COMT Val158Met, clus-terin CLU, neuregulin 1 receptor (ErbB4), neurotrophic tyrosine kinase receptor- type 1 (NTRK1), and the hemochromatosis gene (HFE) which explained ∼6% of the variance in the average FA of the corpus callosum including the genu, body, and splenium in young, healthy individ-uals. Although adding to the combined effect of other SNPs, there was no significant independent effect of COMT Val158Met polymorphism on FA.

The studies showed a sex effect on COMT functioning. In partic-ular, COMT activity in human prefrontal cortex is 17% higher in men than women (Chen et al., 2004). The sexual dimorphism in the nor-mal brain could be due to interaction of estrogens with COMT activ-ity. Estrogens inhibit COMT gene transcription (Xie, Ho, & Ramsden, 1999), while COMT, in turn, participates in the metabolism of estrogens (Worda et al., 2003). This sexual dimorphism is known to con-tribute to significant sex by genotype interaction effects on behavior and personality (Barnett et al., 2008; Chen et al., 2011; Gurvich & Rossell, 2015; Harrison & Tunbridge, 2008) as well as cortical thick-ness (Papaleo, Erickson, Liu, Chen, & Weinberger, 2012; Sannino et al., 2015).

To summarize, the studies reviewed above demonstrated nega-tive associations between Met polymorphism and the white matter myelination. On the other hand, there have been reports of sexual dimorphism on COMT functionality. To the best of our knowledge, there have been no publications exploring possible relationship be-tween COMT polymorphism and white matter structure in people of different sex. We hypothesized that COMT polymorphism would dif-ferentially impact on the strength of FA values in males and females. In particular, we expected to observe sexual dimorphism effects, that is, reduced integrity of white matter tracts in females with Val polymorphism (compared with their male counterparts) due to lower activity of Val polymorphism and putatively higher DA availability in females. In order to make our study comparable with the studies re-viewed as above, we chose to group COMT genotypes according to the presence or absence of the Met allele (i.e., Met/Met + Val/Met vs. Val/Val).

We used a whole- brain diffusion- weighted imaging (DWI) trac-tography method with Tract- Based Spatial Statistics (TBSS) analysis to examine influence of COMT polymorphism on the intrinsic brain networks in a sample of healthy adults. We chose FA as the mea-sure of white matter structure, as it has been shown to have higher

(4)

heritability than other DWI parameters, such as radial and axial diffu-sivity (Kochunov et al., 2010).

2 | MATERIALS AND METHODS

2.1 | Participants

The study included 82 right- handed, White Caucasian, healthy volun-teers (39 men; 43 women; mean age: 33.2 years; range: 19–54 years). The White Caucasian ancestry has been established by participants’ self- report. Exclusion criteria comprised the neuropsychiatric disor-ders in the participants or their first- degree relatives, screened out by the Structured Clinical Interview for DSM- IV (First, Spitzer, Gibbon, & Willimans, 1996). Participants were provided with full information about the study and they gave written consent according to decla-ration of Helsinki. The study was approved by Ethical Committee of King’s College London, Institute of Psychiatry (London, UK).

2.2 | Genotyping

We acknowledge the potential pitfalls associated with neuroimaging genetic studies looking at the effects of a candidate genes on brain function or structure (e.g., Bigos & Weinberger, 2010). These authors suggested a set of basic principles that would assure sufficient power and validity of such a study, for example, a rational approach to the selection of candidate genes, the careful control of nongenetic factors (i.e., sex, age, IQ), and selection of task paradigms that could be plau-sibly linked to the biology of the gene of interest. In our investigation of white matter connectivity, we chose a COMT gene that has been reported to be related to white matter integrity. We also modeled ef-fect of sex as potential factor interacting with the efef-fect of COMT polymorphism.

Cheek swab samples were collected and DNA extracted using the protocol developed at the Social, Genetic and Developmental Psychiatry Centre (King’s College London, Institute of Psychiatry, London, UK) (Freeman et al., 2003). All participants were genotyped for COMT (Val158Met, rs4680). The genotype of the COMT Val158Met (rs4680) SNP was determined by allelic discrimination assay (C__25746809_50) based on fluorogenic 5′ nuclease activity: a TaqMan SNP genotyping assay was performed using an ABI Prism 7900HT and analyzed with Sequence Detection System software according to the manufacturer’s instructions (Applied Biosystems, Warrington, UK). There was no statistical deviation from Hardy–Weinberg equilibrium for all the polymorphisms. The COMT Val/Val homozygosity was de-tected in 19 participants (12 males and 7 females) and 63 participants were Met-carriers (27 males and 36 females).

2.3 | DWI image acquisition

We acquired DWI that uses the water diffusion properties to inves-tigate the microstructural architecture of white matter fibers (Basser, Mattiello, & LeBihan, 1994). FA is a parameter derived from DWI that provides a reliable surrogate of the white fiber microstructural

integrity. All experiments were performed on a 3T scanner (Signa HDx, General Electric, Milwaukee, WI, USA). DWI was acquired on whole- brain volumes with a single- shot echo planar imaging sequence and an 8- channel head coil. Imaging parameters were as follow: TE/ TR = 104/17,910 ms, pixel size = 2.4 × 2.4, slice thickness = 2.4, 32 directions with b value = 1,300 mm2_{/s including four images with no}

diffusion weighting (b value = 0).

2.4 | DWI data preprocessing

Processing of diffusion weighted images was performed using FSL FMRIB’s Software Library (FSL, version 4.1.9, http://www.fmrib.ox.ac. uk/fsl) (Smith et al., 2004). Diffusion- weighted data were corrected for eddy- current distortions and simple head motion artifacts using affine registration to the first acquired volume. Then a binary brain mask image was computed for each subject using Brain Extraction Tool (BET) (Smith, 2002). Finally, FA maps were created from the dif-fusion tensor model employing the FDT difTool (BET) (Smith, 2002). Finally, FA maps were created from the dif-fusion tool.

2.5 | Whole- brain TBSS analysis

Voxelwise statistical analysis of the FA data was carried out using TBSS (Tract- Based Spatial Statistics). TBSS is a useful tool for analyzing FA data as it improves sensitivity, objectivity, and interpret-ability through nonlinear registration with an alignment- invariant tract representation (Smith et al., 2006). All subjects’ FA data were aligned into a common space using the FNIRT (FMRIB’s Non- Linear Image Registration Tool) (Andersson, Jenkinson, & Smith, 2007), which uses a b- spline representation of the registration warp field (Rueckert et al., 1999). Next, a mean FA image was created and thinned to create a mean FA skeleton which represents the centers of all tracts common to the group. Each subject’s aligned FA data were then projected onto this skeleton and the resulting data fed into voxelwise cross- subject statistics. A threshold of FA > 0.2 was applied to exclude areas of uncertain diffusion orientation and/or high intersubject variability.

A permutation program (FSL’s Randomize) was applied to voxel-wise statistics on skeletonized FA data for all subjects. A design and a contrast matrix were performed using General Linear Model (GLM Tools, part of FSL). Next, randomization procedure produced statistical maps so that each pixel value refers to the p- value of the test. The threshold- free cluster enhancement (TFCE) (Smith & Nichols, 2009) and 5,000 permutations options were applied.

The GLM analysis was performed where we have modeled main effects of the COMT (Met-carriers vs. Val homozygotes) and sex, as well as interactions of COMT x sex. The age was considered as a covariate.

2.6 | Volume- of- interest analysis

Although TBSS has been very popular approach for analyzing DWI data, the investigators also reported potential inaccuracies that are inherent in the FA skeleton projection and the substantial bias that it can introduce (see review, Bach et al., 2014). Therefore, in

(5)

4 of 8

|

EL- HAGE EtAL.

order to maximize the robustness and validity of our results we re- evaluated the TBSS data by applying the volume- of- interest analy-sis (VOI). According to Witelson’s method, six parts of the corpus callosum were examined: rostrum, genu and rostral body, anterior midbody, posterior midbody, isthmus, and splenium (Witelson, 1989). By applying a nonlinear spatial normalization (computed during TBBS pro-cedure), the VOI was co- registered to the FA of each subject. Then, the mean FA was computed in the VOI for each subject. Finally, a statistical analysis was performed for each tract using Kruskal– Wallis test.

3 | RESULTS

3.1 | Whole- brain TBSS analysis

The GLM has not produced significant main effects of COMT polymor-phism or sex on FA. However, a COMT effect on FA has been found to be moderated by sex in several regions. In particular, there were significant differences (all p < .05, corrected for multiple comparisons), with FA in male Val/Val > male Met-carriers in the following major white matter tracts: the corpus callosum (CC) (genu, body and sple-nium) and the superior posterior portion of the left superior longitudi-nal fasciculus (SLF). The latter included horizontal fibers that connect superior parietal lobe (SLF- I), angular gyrus (SLF- II), and supramarginal gyrus (SLF- III) with ipsilateral frontal and opercular areas. Significant differences were also observed in the internal capsule which may cor-respond to the inferior fronto- occipital fasciculus (IFOF) and/or the uncinate fasciculus, in the superior part of the cortico- spinal tract (CST), and the anterior, posterior, and superior parts of the corona radiata (ACR, PCR, and SCR, respectively). Results of TBSS are shown in Figure 1.

3.2 | Volume- of- interest TBSS analysis

Using the VOI analysis to verify the results produced by the whole- brain TBSS analysis, we found out that only CC data survived this test. Kruskal–Wallis H- tests showed that, in males only, there was a statistically significant difference in FA values between the Val ho-mozygotes and Met- carriers in the following regions of CC: genu and rostral midbody, anterior midbody, posterior midbody, and isthmus.

Post hoc tests (Mann–Whitney) demonstrated that in all these

con-trasts, male Val homozygotes had higher FA values compared with male Met- carriers (Table 1, Figure 2).

4 | DISCUSSION

Our study demonstrated sexual dimorphism of FA values in various regions of the CC that was associated with COMT Val158Met poly-morphism. In particular, FA values were higher in Val homozygous males than in Met- carriers males, whereas there was no genetic effect on FA values in females.

To the best of our knowledge, there have been only few studies directly investigating the relationships between COMT Val158Met polymorphism and white matter integrity.

Although Thomason et al. (2010) demonstrated higher FA values in genu of corpus callosum in healthy adolescents with Val homozygosity (compared with Met-carriers), Kohannim et al. (2012) did not replicate these findings. The advantageous effect of Val homozygosity on white matter integrity has been reported by Liu et al. (2014), although in dif-ferent brain regions.

Although we have not detected a main effect of genotype, we found that the COMT Val158Met polymorphism effect on FA in genu and rostral midbody of CC was moderated by sex, which adds an im-portant dimension to the COMT functionality.

We have performed additional analysis to estimate potential ef-fects of all variables of no- interest on the hypothesized interaction—to account for all covariates (i.e., sex × age, comt × age, age × sex) as pro-posed by Keller (2014).

The additional analysis supported our original results, that is, FA in male Val homozygotes was higher than in male Met-carriers in corpus callosum, SLF, IFOF, corona radiata, and CST at p < .05.

What are the implications of our finding of genotype- and sex- related effects on CC fractional anisotropy? Corpus callosum contains WM fibers that connect the two hemispheres, and is involved in inter-hemispheric communication (Gazzaniga, 2000). Its known functions include interhemispheric exchange of sensory, motor, and cognitive in-formation, and integration of inputs reaching one or both hemispheres (de Lacoste, Kirkpatrick, & Ross, 1985; Koch et al., 2011; Seltzer & Pandya, 1983; Wahl et al., 2007).

The literature of sex effect on CC size has been inconsistent. Several studies have failed to identify significant CC sex differences (e.g., Hasan et al., 2009; Fling et al., 2011; Westerhausen et al., 2011). A large sample study (Ardekani, Figarsky, & Sidtis, 2013) found that corpus callosum cross- sectional area was larger in females after cor-recting for the confounding effect of brain size (which is usually bigger in males). Another large cohort study (Prendergast et al., 2015), which used the same segmentation of CC as our group (Witelson, 1989), demonstrated main effects for sex when predicting CC length, perim-eter, and circularity (i.e., measure of whole CC shape). In particular, males’ callosa were longer than females, with greater perimeter while controlling for intracranial volume. The authors reported that greater absolute corpus callosum genu values were observed in males until the fifth decade compared with females. Importantly, in a DTI study, Westerhausen et al. (2011) have found the sex effect on genu of CC with FA in males being higher than in females.

Our finding of a sex- specific effect of COMT is in accordance with the literature on the role of COMT in sexual dimorphism. It has been known that estrogen reduces COMT enzyme activity, impacting on the effect of COMT genotype in women relative to men (Harrison & Tunbridge, 2008). Interestingly, sex- dichotomous effects of functional

COMT genetic variations on cognitive functions disappear after

meno-pause (Papaleo et al., 2012).

There is dearth of data on sex- specific effects of COMT genotype on brain white matter. An important study of Zinkstok et al. (2006)

(6)

F I G U R E 1 Genotype effect in

male participants. FA maps. Fractional anisotropy (FA) skeleton is shown in green. To facilitate visualization, regions showing significant FA difference Males

Val homozygotes > Males Met carries are

highlighted in red- yellow (p < .05 corrected for multiple comparisons), Regions showing significant FA difference are thickened using the tbssfill script implemented in FSL. Results are projected on the MNI 152 template and coordinates in MNI 152 space are indicated. L, left; R, right., Corpus Callosum; SLF, Superior Longitudinal Fasciculus; IFOF, inferior fronto-occipital fasciculus; ACR, PCR, SCR, Anterior, Posterior, Superior Corona Radiata; CST, Cortico- Spinal Tract. (a) Axial views. (b) Sagittal views ACR CC CC genu L R z=-7mm z=-3mm z=6mm z=16mm z=23mm z=42mm z=52mm splenium CC genu z=32mm CC body CST SLF PCR SCR ext. capsule ACR int. capsule (IFOF) IFOF (IFOF) ACR CC genu x=-24mm x=-16mm x=-8mm x=0mm x=8mm x=24mm x=32mm CC genu x=16mm PCR SCR ext. capsule ACR int. capsule CC body CC body CC splenium CC splenium CC splenium CC genu PCR x=20mm CC body CC body CC body CC genu PCR ACR ACR ACR (a) (b) T A B L E 1 Fractional anisotropy (FA) in corpus callosum (means and standard deviations) Males (39) Females (43)

Val/Val (12) Met-carriers (27) p Val/Val (7) Met-carriers (36) p

Rostrum 0.487 ± 0.006 0.470 ± 0.004 ns 0.483 ± 0.007 0.480 ± 0.003 ns Genu and rostral midbody 0.561 ± 0.006a _{0.529 ± 0.006} _<.01 _{0.546 ± 0.010} _{0.539 ± 0.004}a _ns Anterior midbody 0.595 ± 0.008 0.561 ± 0.007 <.01 0.586 ± 0.011 0.575 ± 0.004 ns Posterior midbody 0.559 ± 0.009 0.518 ± 0.008 <.05 0.537 ± 0.015 0.541 ± 0.004 ns Isthmus 0.624 ± 0.007 0.594 ± 0.007 <.05 0.611 ± 0.009 0.611 ± 0.003 ns Splenium 0.669 ± 0.008 0.653 ± 0.006 ns 0.670 ± 0.005 0.666 ± 0.003 ns a_{Val/Val males > Met females, p < .05.}

(7)

6 of 8

|

EL- HAGE EtAL.

found that in young (18–35 years old) female but not male Met ho-mozygotes, decreased white matter in left corpus callosum was as-sociated with increasing age. The authors suggested that these differences could be related to estrogen- related down- regulation of

COMT expression.

Our data showed that the difference between Val and Met activity may not be as pronounced in females compared with males—which should be taken into account when examining gene × sex interactions. For example, White et al. (2014) showed direct sex modulation of

COMT effects on prefrontal activity. Male Val homozygotes exhibited

significantly elevated activation compared with male heterozygotes. By contrast, corresponding COMT effects were less robust in females. This was interpreted as a compromised efficiency of prefrontal cor-tex in male Val carriers. However, these results could be explained in light of sexual dimorphism, for example, the Val effect in females could be inhibited (and appear comparable to Met) due to the impact of estrogen.

A differential effect of COMT polymorphism in males and in fe-males might contribute to the inconsistencies in the literature on the association of COMT genotype with some behavioral pheno-types. In particular, COMT Val carriers demonstrated an impaired performance and higher number of errors in the Wisconsin Card Sorting Test compared to Met/Met individuals (Barnett et al., 2008; Joober et al., 2002; Rosa et al., 2004). Similarly, studies using working memory tasks in humans (or mice) showed that COMT

Val carriers (and mice with artificially increased COMT activity)

performed poorer compared to COMT Met- carriers (and wild- type mice) (Egan et al., 2001; Papaleo et al., 2012; Scheggia, Sannino, Scattoni, & Papaleo, 2012; Tunbridge, Harrison, & Weinberger, 2006). The other studies have reported no association between

COMT Val158Met and performance in the WCST (Ho, Wassink,

O’Leary, Sheffield, & Andreasen, 2005; Tsai et al., 2003) and the working memory task (Jacobs & D’Esposito, 2011). In light of our results of a sex- specific effect of COMT on brain white matter (CC), it would be interesting to further examine whether these dis-crepancies potentially might be explained by sex effect on COMT functionality.

4.1 | Limitations

Although our sample size was reasonably large, there were small num-bers in some genotype groups, for example, Val homozygotes were represented by 12 males and 7 females. We have ensured that the Type 1 error has been controlled for by most rigorous two- stage sta-tistics, that is, the whole- brain TBSS with subsequent nonparametric VOI analysis.

Another limitation of this study is that the individual plasma levels of estrogen were not assessed; therefore, we were unable to exclude any individual variation in estrogen levels. We assumed that in our group of healthy women (aged from 19 to 54), the levels of estrogen were within healthy range. Our conclusions on the inhibitory effect of estrogen on COMT activity have been based on existing literature.

5 | CONCLUSIONS

To the best of our knowledge, this is the first study to examine the effects of sex and COMT polymorphisms on white matter connec-tivity in healthy adults. We found sex- specific effect of COMT on brain white matter (CC): male Val homozygotes had significantly higher white matter integrity compared with Met-carriers. This ef-fect was absent in females where Val and Met groups had almost similar FA values in CC.

We believe that the importance of our results lies in highlighting the often overlooked joint effect of gene and sex on integrity of white matter tracts. Further research on larger samples is warranted that may shed more light on the sexually dimorphic effect of COMT on neuroanatomical structures.

ACKNOWLEDGMENTS

The authors thank Nadia Aguillon- Hernandez (PhD, INSERM U930 Imaging and Brain, University François- Rabelais of Tours, University Hospital of Tours, France) for her advice on statistical analyses.

REFERENCES

Andersson, J. L. R., Jenkinson, M., & Smith, S. (2007). Non-linear

registra-tion, aka spatial normalisation. Technical Report TR07JA2. Oxford, UK:

Oxford Centre for Functional Magnetic Resonance Imaging of the Brain, Department of Clinical Neurology, Oxford University. Available at http://www.fmrib.ox.ac.uk/analysis/techrep for downloading. Ardekani, B. A., Figarsky, K., & Sidtis, J. J. (2013). Sexual dimorphism in the human corpus callosum: An MRI study using the OASIS brain database. Cerebral Cortex, 23, 2514–2520. Bach, M., Laun, F. B., Leemans, A., Tax, C. M. W., Biessels, G. J., Stieltjes, B., & Maier-Hein, K. H. (2014). Methodological considerations on tract- based spatial statistics (TBSS). NeuroImage, 100, 358–369.

Barnett, J. H., Scoriels, L., & Munafò, M. R. (2008). Meta- analysis of the cognitive effects of the catechol- O- methyltransferase gene Val158/108Met polymorphism. Biological Psychiatry, 64, 137–144. Bartzokis, G. (2011). Neuroglialpharmacology: White matter

pathophysi-ologies and psychiatric treatments. Frontiers in Bioscience (Landmark

Edition), 16, 2695–2733.

F I G U R E 2 Genotype effect on fractional anisotropy in genu and

rostral midbody in males and females (*p < .05; **p < .01). Blue bars:

Val homozygotes; Orange bars: Met-carriers

0.5 0.51 0.52 0.53 0.54 0.55 0.56 0.57 0.58 Female Male FA values Groups

Val homozygotes Met carriers

**

*

(8)

Basser, P. J., Mattiello, J., & LeBihan, D. (1994). MR diffusion tensor spec-troscopy and imaging. Biophysical Journal, 66, 259–267.

Bertocci, B., Miggiano, V., Da Prada, M., Dembic, Z., Lahm, H. W., & Malherbe, P. (1991). Human catechol- O- methyltransferase: Cloning and expression of the membrane- associated form. Proceedings of

the National Academy of Sciences of the United States of America, 88,

1416–1420.

Bigos, K. L., & Weinberger, D. R. (2010). Imaging genetics–days of future past. NeuroImage, 53, 804–809.

Chen, C., Chen, C., Moyzis, R., Dong, Q., He, Q., Zhu, B., & Lessard, J. (2011). Sex modulates the associations between the COMT gene and personality traits. Neuropsychopharmacology, 36, 1593–1598. Chen, J., Lipska, B. K., Halim, N., Ma, Q. D., Matsumoto, M., Melhem, S.,

& Weinberger, D. R. (2004). Functional analysis of genetic variation in catechol- O- methyltransferase (COMT): Effects on mRNA, protein, and enzyme activity in postmortem human brain. American Journal of

Human Genetics, 75, 807–821.

Deutch, A. Y., & Roth, R. H. (1990). The determinants of stress- induced ac-tivation of the prefrontal cortical dopamine system. Progress in Brain

Research, 85, 367–402; discussion 402–403.

Egan, M. F., Goldberg, T. E., Kolachana, B. S., Callicott, J. H., Mazzanti, C. M., Straub, R. E., & Weinberger, D. R. (2001). Effect of COMT Val108/158 Met genotype on frontal lobe function and risk for schizophrenia.

Proceedings of the National Academy of Sciences of the United States of America, 98, 6917–6922.

First, M. B., Spitzer, R. L., Gibbon, M., & Willimans, J. (1996). Structured

clinical interview for DSM-IV axis I disorders (SCID-I/P, Version 2.0.). New

York: Biometrics Research Department, New York State Psychiatric Institute.

Fling, B. W., Chapekis, M., Reuter-Lorenz, P. A., Anguera, J., Bo, J., Langan, J., & Seidler, R. D. (2011). Age differences in callosal contributions to cognitive processes. Neuropsychologia, 49, 2564–2569.

Freeman, B., Smith, N., Curtis, C., Huckett, L., Mill, J., & Craig, I. W. (2003). DNA from buccal swabs recruited by mail: Evaluation of storage effects on long- term stability and suitability for multiplex polymerase chain re-action genotyping. Behavior Genetics, 33, 67–72.

Gazzaniga, M. S. (2000). Cerebral specialization and interhemispheric com-munication: Does the corpus callosum enable the human condition?

Brain, 123, 1293–1326.

Goldberg, T. E., Egan, M. F., Gscheidle, T., Coppola, R., Weickert, T., Kolachana, B. S., & Weinberger, D. R. (2003). Executive subprocesses in working memory: Relationship to catechol- O- methyltransferase Val158Met genotype and schizophrenia. Archives of General Psychiatry,

60, 889–896.

Grossman, M. H., Emanuel, B. S., & Budarf, M. L. (1992). Chromosomal mapping of the human catechol- O- methyltransferase gene to 22q11.1→q11.2. Genomics, 12, 822–825.

Gurvich, C., & Rossell, S. L. (2015). Dopamine and cognitive control: Sex- by- genotype interactions influence the capacity to switch attention.

Behavioral Brain Research, 281, 96–101.

Harrison, P. J., & Tunbridge, E. M. (2008). Catechol- O- methyltransferase (COMT): A gene contributing to sex differences in brain function, and to sexual dimorphism in the predisposition to psychiatric disorders.

Neuropsychopharmacology, 33, 3037–3045.

Hasan, K. M., Kamali, A., Iftikhar, A., Kramer, L. A., Papanicolaou, A. C., Fletcher, J. M., & Ewing-Cobbs, L. (2009). Diffusion tensor tractography quantification of the human corpus callosum fiber pathways across the lifespan. Brain Research, 1249, 91–100.

Ho, B. C., Wassink, T. H., O’Leary, D. S., Sheffield, V. C., & Andreasen, N. C. (2005). Catechol- O- methyl transferase Val158Met gene polymorphism in schizophrenia: Working memory, frontal lobe MRI morphology and frontal cerebral blood flow. Molecular Psychiatry, 10(229), 287–298. Jacobs, E., & D’Esposito, M. (2011). Estrogen shapes dopamine- dependent

cognitive processes: Implications for women’s health. Journal of

Neuroscience, 31, 5286–5293.

Joober, R., Gauthier, J., Lal, S., Bloom, D., Lalonde, P., Rouleau, G., & Labelle, A. (2002). Catechol- O- methyltransferase Val- 108/158- Met gene vari-ants associated with performance on the Wisconsin Card Sorting Test.

Archives of General Psychiatry, 59, 662–663.

Keller, M. C. (2014). Gene × environment interaction studies have not prop-erly controlled for potential confounders: the problem and the (simple) solution. Biological Psychiatry, 75, 18–24.

Koch, G., Cercignani, M., Bonnì, S., Giacobbe, V., Bucchi, G., Versace, V., & Bozzali, M. (2011). Asymmetry of parietal interhemispheric connec-tions in humans. Journal of Neuroscience, 31, 8967–8975.

Kochunov, P., Glahn, D. C., Lancaster, J. L., Winkler, A. M., Smith, S., Thompson, P. M., & Blangero, J. (2010). Genetics of microstructure of cerebral white matter using diffusion tensor imaging. NeuroImage, 53, 1109–1116.

Kohannim, O., Jahanshad, N., Braskie, M. N., Stein, J. L., Chiang, M. C., Reese, A. H., & Thompson, P. M. (2012). Predicting white matter integ-rity from multiple common genetic variants. Neuropsychopharmacology,

37, 2012–2019.

Lachman, H. M., Papolos, D. F., Saito, T., Yu, Y. M., Szumlanski, C. L., & Weinshilboum, R. M. (1996). Human catechol- O- methyltransferase pharmacogenetics: Description of a functional polymorphism and its potential application to neuropsychiatric disorders. Pharmacogenetics,

6, 243–250.

de Lacoste, M. C., Kirkpatrick, J. B., & Ross, E. D. (1985). Topography of the human corpus callosum. Journal of Neuropathology and Experimental

Neurology, 44, 578–591.

Liu, M. E., Huang, C. C., Yang, A. C., Tu, P. C., Yeh, H. L., Hong, C. J., & Tsai, S. J. (2014). Catechol- O- methyltransferase Val158Met polymorphism on the relationship between white matter hyperintensity and cognition in healthy people. PLoS ONE, 9, e88749.

Liu, B., Li, J., Yu, C., Li, Y., Liu, Y., Song, M., & Jiang, T. (2010). Haplotypes of catechol- O- methyltransferase modulate intelligence- related brain white matter integrity. NeuroImage, 50, 243–249.

Lotta, T., Vidgren, J., Tilgmann, C., Ulmanen, I., Melén, K., Julkunen, I., & Taskinen, J. (1995). Kinetics of human soluble and membrane- bound catechol O- methyltransferase: A revised mechanism and description of the thermolabile variant of the enzyme. Biochemistry, 34, 4202–4210. Malhotra, A. K., Kestler, L. J., Mazzanti, C., Bates, J. A., Goldberg, T., &

Goldman, D. (2002). A functional polymorphism in the COMT gene and performance on a test of prefrontal cognition. American Journal of

Psychiatry, 159, 652–654.

Männistö, P. T., & Kaakkola, S. (1999). Catechol- O- methyltransferase (COMT): Biochemistry, molecular biology, pharmacology, and clini-cal efficacy of the new selective COMT inhibitors. Pharmacologiclini-cal

Reviews, 51, 593–628.

Mattay, V. S., Goldberg, T. E., Fera, F., Hariri, A. R., Tessitore, A., Egan, M. F., & Weinberger, D. R. (2003). Catechol O- methyltransferase val158- met genotype and individual variation in the brain response to amphet-amine. Proceedings of the National Academy of Sciences of the United

States of America, 100, 6186–6191.

Meyer-Lindenberg, A., & Weinberger, D. R. (2006). Intermediate pheno-types and genetic mechanisms of psychiatric disorders. Nature Reviews

Neuroscience, 7, 818–827.

Mier, D., Kirsch, P., & Meyer-Lindenberg, A. (2010). Neural substrates of pleiotropic action of genetic variation in COMT: A meta- analysis.

Molecular Psychiatry, 15, 918–927.

Minzenberg, M. J., Xu, K., Mitropoulou, V., Harvey, P. D., Finch, T., Flory, J. D., & Siever, L. J. (2006). Catechol- O- methyltransferase Val158Met genotype variation is associated with prefrontal- dependent task per-formance in schizotypal personality disorder patients and comparison groups. Psychiatric Genetics, 16, 117–124.

Money, K. M., & Stanwood, G. D. (2013). Developmental origins of brain disorders: Roles for dopamine. Frontiers in Cellular Neuroscience, 7, 260. Nickl-Jockschat, T., Janouschek, H., Eickhoff, S. B., & Eickhoff, C. R. (2015).

(9)

8 of 8

|

EL- HAGE EtAL. genotype on brain activation during working memory tasks. Biological

Psychiatry, 78, e43–e46.

Papaleo, F., Erickson, L., Liu, G., Chen, J., & Weinberger, D. R. (2012). Effects of sex and COMT genotype on environmentally modulated cognitive control in mice. Proceedings of the National Academy of Sciences of the

United States of America, 109, 20160–20165.

Prendergast, D. M., Ardekani, B., Ikuta, T., John, M., Peters, B., DeRosse, P., & Szeszko, P. R. (2015). Age and sex effects on corpus callosum mor-phology across the lifespan. Human Brain Mapping, 36, 2691–2702. Rosa, A., Peralta, V., Cuesta, M. J., Zarzuela, A., Serrano, F., Martínez-Larrea,

A., & Fañanás, L. (2004). New evidence of association between COMT gene and prefrontal neurocognitive function in healthy individuals from sibling pairs discordant for psychosis. American Journal of Psychiatry,

161, 1110–1112.

Rueckert, D., Sonoda, L. I., Hayes, C., Hill, D. L., Leach, M. O., & Hawkes, D. J. (1999). Nonrigid registration using free- form deformations: Application to breast MR images. IEEE Transactions on Medical Imaging,

18, 712–721.

Sannino, S., Gozzi, A., Cerasa, A., Piras, F., Scheggia, D., Managò, F., & Papaleo, F. (2015). COMT genetic reduction produces sexually diver-gent effects on cortical anatomy and working memory in mice and hu-mans. Cerebral Cortex, 25, 2529–2541.

Scheggia, D., Sannino, S., Scattoni, M. L., & Papaleo, F. (2012). COMT as a drug target for cognitive functions and dysfunctions. CNS & Neurological

Disorders Drug Targets, 11, 209–221.

Seltzer, B., & Pandya, D. N. (1983). The distribution of posterior parietal fibers in the corpus callosum of the rhesus monkey. Experimental Brain

Research, 49, 147–150. Shimony, J. S., McKinstry, R. C., Akbudak, E., Aronovitz, J. A., Snyder, A. Z., Lori, N. F., & Conturo, T. E. (1999). Quantitative diffusion- tensor anisot-ropy brain MR imaging: Normative human data and anatomic analysis. Radiology, 212, 770–784. Smith, S. M. (2002). Fast robust automated brain extraction. Human Brain Mapping, 17, 143–155. Smith, S. M., Jenkinson, M., Johansen-Berg, H., Rueckert, D., Nichols, T. E., Mackay, C. E., & Behrens, T. E. J. (2006). Tract- based spatial statistics: Voxelwise analysis of multi- subject diffusion data. NeuroImage, 31, 1487–1505.

Smith, S. M., Jenkinson, M., Woolrich, M. W., Beckmann, C. F., Behrens, T. E. J., Johansen-Berg, H., & Matthews, P. M. (2004). Advances in func-tional and structural MR image analysis and implementation as FSL.

NeuroImage, 23, S208–S219.

Smith, S. M., & Nichols, T. E. (2009). Threshold- free cluster enhancement: Addressing problems of smoothing, threshold dependence and locali-sation in cluster inference. NeuroImage, 44, 83–98.

Thomason, M. E., Dougherty, R. F., Colich, N. L., Perry, L. M., Rykhlevskaia, E. I., Louro, H. M., … Gotlib, I. H. (2010). COMT genotype affects pre-frontal white matter pathways in children and adolescents. NeuroImage,

53, 926–934.

Tsai, S. J., Yu, Y. W. Y., Chen, T. J., Chen, J. Y., Liou, Y. J., Chen, M. C., & Hong, C. J. (2003). Association study of a functional catechol- O- methyltransferase- gene polymorphism and cognitive function in healthy females. Neuroscience Letters, 338, 123–126.

Tunbridge, E. M., Bannerman, D. M., Sharp, T., & Harrison, P. J. (2004). Catechol- O- methyltransferase inhibition improves set- shifting perfor-mance and elevates stimulated dopamine release in the rat prefrontal cortex. Journal of Neuroscience, 24, 5331–5335.

Tunbridge, E. M., Harrison, P. J., & Weinberger, D. R. (2006). Catechol- o- methyltransferase, cognition, and psychosis: Val158Met and beyond.

Biological Psychiatry, 60, 141–151.

Wahl, M., Lauterbach-Soon, B., Hattingen, E., Jung, P., Singer, O., Volz, S., & Ziemann, U. (2007). Human motor corpus callosum: Topography, somatotopy, and link between microstructure and function. Journal of

Neuroscience, 27, 12132–12138.

Wardle, M. C., de Wit, H., Penton-Voak, I., Lewis, G., & Munafò, M. R. (2013). Lack of association between COMT and working memory in a population- based cohort of healthy young adults.

Westerhausen, R., Kompus, K., Dramsdahl, M., Falkenberg, L. E., Grüner, R., Hjelmervik, H., & Hugdahl, K. (2011). A critical re- examination of sexual dimorphism in the corpus callosum microstructure. NeuroImage,

56, 874–880.

White, T. P., Loth, E., Rubia, K., Krabbendam, L., Whelan, R., Banaschewski, T., & Schumann, G. (2014). Sex differences in COMT polymor-phism effects on prefrontal inhibitory control in adolescence.

Witelson, S. F. (1989). Hand and sex differences in the isthmus and genu of the human corpus callosum. A postmortem morphological study. Brain,

112, 799–835.

Worda, C., Sator, M. O., Schneeberger, C., Jantschev, T., Ferlitsch, K., & Huber, J. C. (2003). Influence of the catechol- O- methyltransferase (COMT) codon 158 polymorphism on estrogen levels in women.

Human Reproduction, 18, 262–266.

Xie, T., Ho, S. L., & Ramsden, D. (1999). Characterization and implications of estrogenic down- regulation of human catechol- O- methyltransferase gene transcription. Molecular Pharmacology, 56, 31–38.

Xu, H., Yang, H. J., McConomy, B., Browning, R., & Li, X. M. (2010). Behavioral and neurobiological changes in C57BL/6 mouse exposed to cuprizone: Effects of antipsychotics. Frontiers in Behavioural Neurosciences, 4, 8. Xu, H., Yang, H. J., Zhang, Y., Clough, R., Browning, R., & Li, X. M. (2009).

Behavioral and neurobiological changes in C57BL/6 mice exposed to cuprizone. Behavioral Neuroscience, 123, 418–429.

Zinkstok, J., Schmitz, N., van Amelsvoort, T., de Win, M., van den Brink, W., Baas, F., & Linszen, D. (2006). The COMT val158met polymorphism and brain morphometry in healthy young adults. Neuroscience Letters,

405, 34–39.

How to cite this article: El-Hage W, Cléry H, Andersson F,

et al. Sex- specific effects of COMT Val158Met polymorphism on corpus callosum structure: A whole- brain diffusion- weighted imaging study. Brain Behav. 2017;7:e00786. https://doi.org/10.1002/brb3.786